Power fluctuations in sheared amorphous materials: A minimal model
Abstract
The importance of mesoscale fluctuations in flowing amorphous materials is widely accepted, without a clear understanding of their role. We propose a mean-field elastoplastic model that admits both stress and strain-rate fluctuations, and investigate the character of its power distribution under steady shear flow. The model predicts the suppression of negative power fluctuations near the liquid-solid transition; the existence of a fluctuation relation in limiting regimes but its replacement in general by stretched-exponential power-distribution tails; and a crossover between two distinct mechanisms for negative power fluctuations in the liquid and the yielding solid phases. We connect these predictions with recent results from particle-based, numerical micro-rheological experiments.
Cite
@article{arxiv.2106.12962,
title = {Power fluctuations in sheared amorphous materials: A minimal model},
author = {Timothy Ekeh and Étienne Fodor and Suzanne M. Fielding and Michael E. Cates},
journal= {arXiv preprint arXiv:2106.12962},
year = {2022}
}
Comments
11 pages, 4 figures